Mobile communication system, receiving device, and method

1. A receiving device for a mobile communication system employing a single-carrier multiple-input multiple-output (MIMO) transmission scheme where Fourier-transformed and weighted symbols in a transmission symbol sequence are mapped to subcarriers, inverse-Fourier-transformed, and then transmitted from multiple transmitting antennas, the receiving device comprising: an extracting unit configured to Fourier-transform signals received by multiple receiving antennas and to extract signal components mapped to the subcarriers from the signals; and a signal detection unit configured to estimate the symbols transmitted via the subcarriers by applying a QR decomposition algorithm to the extracted signal components, wherein the signal detection unit includes a decomposition unit configured to obtain a unitary matrix such that a product of the unitary matrix and a triangular matrix equals a product of a weight matrix determining a correspondence between the transmission symbol sequence and the subcarriers and a channel matrix indicating radio channel conditions between the transmitting antennas and the receiving antennaes; and an estimation unit configured to estimate candidates of the symbols transmitted from the transmitting antennas based on the triangular matrix and a vector obtained by multiplying a received vector, which includes the signal components received by the receiving antennas, by the unitary matrix.

2. The receiving device as claimed in claim 1 , wherein the signal detection unit further includes a determining unit configured to calculate metrics for the respective candidates of the symbols and to narrow down the candidates based on the metrics, the metrics indicating square Euclidean distances on a symbol constellation between received symbols and the candidates of the symbols.

3. The receiving device as claimed in claim 1 , further comprising: a permutation control unit configured to input a control signal for permuting rows or columns of a matrix product of the channel matrix and the weight matrix to the decomposition unit, wherein the decomposition unit is configured to obtain the triangular matrix and the unitary matrix such that the product of the triangular matrix and the unitary matrix equals the matrix product the rows or the columns of which are permuted according to the control signal.

4. The receiving device as claimed in claim 3 , wherein the permutation control unit is configured to generate the control signal such that when the estimation unit estimates the symbols according to an M algorithm, the symbols from one of the transmitting antennas corresponding to higher received power are estimated prior to the symbols from another one of the transmitting antennas corresponding to lower received power.

5. The receiving device as claimed in claim 3 , wherein the permutation control unit is configured to generate the control signal such that the estimation unit estimates a first subcarrier component of the symbols transmitted from a first one of the transmitting antennas and then estimates a first subcarrier component of the symbols transmitted from a second one of the transmitting antennas.

6. A mobile communication system employing a single-carrier multiple-input multiple-output (MIMO) transmission scheme, comprising: a transmitting device including a mapping unit configured to map Fourier-transformed and weighted symbols in a transmission symbol sequence to subcarriers, an inverse Fourier transform unit configured to inverse-Fourier-transform the mapped symbols, and a transmitting unit configured to transmit a signal including the inverse-Fourier-transformed symbols from multiple transmitting antennas; and a receiving device including an extracting unit configured to Fourier-transform signals received by multiple receiving antennas and to extract signal components mapped to the subcarriers from the signals, and a signal detection unit configured to estimate the symbols transmitted via the subcarriers by applying a QR decomposition algorithm to the extracted signal components, wherein the signal detection unit includes a decomposition unit configured to obtain a unitary matrix such that a product of the unitary matrix and a triangular matrix equals a product of a weight matrix determining a correspondence between the transmission symbol sequence and the subcarriers and a channel matrix indicating radio channel conditions between the transmitting antennas and the receiving antennas; and an estimation unit configured to estimate candidates of the symbols transmitted from the transmitting antennas based on the triangular matrix and a vector obtained by multiplying a received vector, which includes the signal components received by the receiving antennas, by the unitary matrix.

7. The mobile communication system as claimed in claim 6 , wherein the transmitting device is included in a user device and the receiving device is included in a base station.

8. A method for a mobile communication system employing a single-carrier multiple-input multiple-output (MIMO) transmission scheme and including a transmitting device and a receiving device, the method comprising: the steps, performed by the transmitting device, of mapping Fourier-transformed and weighted symbols in a transmission symbol sequence to subcarriers, inverse-Fourier-transforming the mapped symbols, and transmitting a signal including the inverse-Fourier-transformed symbols from multiple transmitting antennas; and the steps, performed by the receiving device, of Fourier-transforming signals received by multiple receiving antennas and extracting signal components mapped to the subcarriers from the signals, and estimating the symbols transmitted via the subcarriers by applying a QR decomposition algorithm to the extracted signal components, wherein in the estimating step, a unitary matrix is obtained such that a product of the unitary matrix and a triangular matrix equals a product of a weight matrix determining a correspondence between the transmission symbol sequence and the subcarriers and a channel matrix indicating radio channel conditions between the transmitting antennas and the receiving antennas, and candidates of the symbols transmitted from the transmitting antennas are estimated based on the triangular matrix and a vector obtained by multiplying a received vector, which includes the signal components received by the receiving antennas, by the unitary matrix.